fbpx
Wikipedia

Laboratory robotics

February 06, 2023

Laboratory robotics is the act of using robots in biology, chemistry or engineering labs. For example, pharmaceutical companies employ robots to move biological or chemical samples around to synthesize novel chemical entities or to test pharmaceutical value of existing chemical matter.[1][2] Advanced laboratory robotics can be used to completely automate the process of science, as in the Robot Scientist project.[3]

Laboratory robots doing acid digestion chemical analysis.

Laboratory processes are suited for robotic automation as the processes are composed of repetitive movements (e.g., pick/place, liquid/solid additions, heating/cooling, mixing, shaking, and testing). Many laboratory robots are commonly referred as autosamplers, as their main task is to provide continuous samples for analytical devices.

History

The first compact computer controlled robotic arms appeared in the early 1980s, and have continuously been employed in laboratories since then.[4] These robots can be programmed to perform many different tasks, including sample preparation and handling.

Yet in the early 1980s, a group led by Masahide Sasaki, from Kochi Medical School, introduced the first fully automated laboratory employing several robotic arms working together with conveyor belts and automated analyzers.[4][5] The success of Sasaki's pioneer efforts made other groups around the world to adopt the approach of Total Laboratory Automation (TLA).

Despite the undeniable success of TLA, its multimillion-dollar cost prevented that most laboratories adopted it.[6] Also, the lack of communication between different devices slowed down the development of automation solutions for different applications, while contributing to keeping costs high. Therefore, the industry attempted several times to develop standards that different vendors would follow in order to enable communication between their devices.[6][7] However, the success of this approach has been only partial, as nowadays many laboratories still do not employ robots for many tasks due to their high costs.

Recently, a different solution for the problem became available, enabling the use of inexpensive devices, including open-source hardware,[8] to perform many different tasks in the laboratory. This solution is the use of scripting languages that can control mouse clicks and keyboard inputs, like AutoIt.[9] This way, it is possible to integrate any device by any manufacturer as long as they are controlled by a computer, which is often the case.

Another important development in robotics which has important potential implications for laboratories is the arrival of robots that do not demand special training for their programming, like Baxter, the robot.

Applications

Low-cost laboratory robotics

 
Low-cost robotic arm used as an autosampler.

The high cost of many laboratory robots has inhibited their adoption. However, currently there are many robotic devices that have very low cost, and these could be employed to do some jobs in a laboratory. For example, a low-cost robotic arm was employed to perform several different kinds of water analysis, without loss of performance compared to much more expensive autosamplers.[10] Alternatively, the autosampler of a device can be used with another device,[9] thus avoiding the need for purchasing a different autosampler or hiring a technician for doing the job. The key aspects to achieve low-cost in laboratory robotics are 1) the use of low-cost robots, which become more and more common, and 2) the use of scripting, which enables compatibility between robots and other analytical equipment.[11]

Robotic, mobile laboratory operators and remote-controlled laboratories

In July 2020 scientists reported the development of a mobile robot chemist and demonstrate that it can assist in experimental searches. According to the scientists their strategy was automating the researcher rather than the instruments – freeing up time for the human researchers to think creatively – and could identify photocatalyst mixtures for hydrogen production from water that were six times more active than initial formulations. The modular robot can operate laboratory instruments, work nearly around the clock, and autonomously make decisions on his next actions depending on experimental results.[12][13]

There is ongoing development of "remote controlled laboratories" that automatically perform many life sciences experiments per day and can be operated, including in collaboration, from afar.[14]

Pharmaceutical applications

One major area where automated synthesis has been applied is structure determination in pharmaceutical research. Processes such as NMR and HPLC-MS can now have sample preparation done by robotic arm.[15] Additionally, structural protein analysis can be done automatically using a combination of NMR and X-ray crystallography. Crystallization often takes hundreds to thousands of experiments to create a protein crystal suitable for X-ray crystallography.[16] An automated micropipet machine can allow nearly a million different crystals to be created at once, and analyzed via X-ray crystallography.

Reproducibility verification

This section is an excerpt from Replication crisis § Semi-automated.[edit]
 
"The overall process of testing the reproducibility and robustness of the cancer biology literature by robot. First, text mining is used to extract statements about the effect of drugs on gene expression in breast cancer. Then two different teams semi-automatically tested these statements using two different protocols, and two different cell lines (MCF7 and MDA-MB-231) using the laboratory automation system Eve."
Researchers demonstrated a way of semi-automated testing for reproducibility: statements about experimental results were extracted from, as of 2022 non-semantic, gene expression cancer research papers and subsequently reproduced via robot scientist "Eve".[17][18] Problems of this approach include that it may not be feasible for many areas of research and that sufficient experimental data may not get extracted from some or many papers even if available.

Diagnostic testing for pathogens

See also: Medical diagnosis and Diagnostic robot

For example, there are robots that are used to analyze swabs from patients to diagnose COVID-19.[19][20][21] Automated robotic liquid handling systems have been or are being built for lateral flow assays. It minimizes hands-on time, maximizes experiment size, and enables improved reproducibility.[22]

Biological laboratory robotics

 
An example of pipettes and microplates manipulated by an anthropomorphic robot (Andrew Alliance)

Biological and chemical samples, in either liquid or solid state, are stored in vials, plates or tubes. Often, they need to be frozen and/or sealed to avoid contamination or to retain their biological and/or chemical properties. Specifically, the life science industry has standardized on a plate format, known as the microtiter plate,[23] to store such samples.

The microtiter plate standard was formalized by the Society for Biomolecular Screening in 1996.[24] It typically has 96, 384 or even 1536 sample wells arranged in a 2:3 rectangular matrix. The standard governs well dimensions (e.g. diameter, spacing and depth) as well as plate properties (e.g. dimensions and rigidity).

A number of companies have developed robots to specifically handle SBS microplates. Such robots may be liquid handlers which aspirates or dispenses liquid samples from and to these plates, or "plate movers" which transport them between instruments.

Other companies have pushed integration even further: on top of interfacing to the specific consumables used in biology, some robots (Andrew[25] by Andrew Alliance, see picture) have been designed with the capability of interfacing to volumetric pipettes used by biologists and technical staff. Essentially, all the manual activity of liquid handling can be performed automatically, allowing humans spending their time in more conceptual activities.

Instrument companies have designed plate readers which can carry out detect specific biological, chemical or physical events in samples stored in these plates. These readers typically use optical and/or computer vision techniques to evaluate the contents of the microtiter plate wells.

One of the first applications of robotics in biology was peptide and oligonucleotide synthesis. One early example is the polymerase chain reaction (PCR) which is able to amplify DNA strands using a thermal cycler to micromanage DNA synthesis by adjusting temperature using a pre-made computer program. Since then, automated synthesis has been applied to organic chemistry and expanded into three categories: reaction-block systems, robot-arm systems, and non-robotic fluidic systems.[26] The primary objective of any automated workbench is high-throughput processes and cost reduction.[27] This allows a synthetic laboratory to operate with a fewer number of people working more efficiently.

Combinatorial library synthesis

Robotics have applications with combinatorial chemistry which has great impact on the pharmaceutical industry. The use of robotics has allowed for the use of much smaller reagent quantities and mass expansion of chemical libraries. The "parallel synthesis" method can be improved upon with automation. The main disadvantage to "parallel-synthesis" is the amount of time it takes to develop a library, automation is typically applied to make this process more efficient.

The main types of automation are classified by the type of solid-phase substrates, the methods for adding and removing reagents, and design of reaction chambers. Polymer resins may be used as a substrate for solid-phase.[28] It is not a true combinatorial method in the sense that "split-mix" where a peptide compound is split into different groups and reacted with different compounds. This is then mixed back together split into more groups and each groups is reacted with a different compound. Instead the "parallel-synthesis" method does not mix, but reacts different groups of the same peptide with different compounds and allows for the identification of the individual compound on each solid support. A popular method implemented is the reaction block system due to its relative low cost and higher output of new compounds compared to other "parallel-synthesis" methods. Parallel-Synthesis was developed by Mario Geysen and his colleagues and is not a true type of combinatorial synthesis, but can be incorporated into a combinatorial synthesis.[29] This group synthesized 96 peptides on plastic pins coated with a solid support for the solid phase peptide synthesis. This method uses a rectangular block moved by a robot so that reagents can be pipetted by a robotic pipetting system. This block is separated into wells which the individual reactions take place. These compounds are later cleaved from the solid-phase of the well for further analysis. Another method is the closed reactor system which uses a completely closed off reaction vessel with a series of fixed connections to dispense. Though the produce fewer number of compounds than other methods, its main advantage is the control over the reagents and reaction conditions. Early closed reaction systems were developed for peptide synthesis which required variations in temperature and a diverse range of reagents. Some closed reactor system robots have a temperature range of 200°C and over 150 reagents.

Purification

Simulated distillation, a type of gas chromatography testing method used in the petroleum, can be automated via robotics. An older method used a system called ORCA (Optimized Robot for Chemical Analysis) was used for the analysis of petroleum samples by simulated distillation (SIMDIS). ORCA has allowed for shorter analysis times and has reduced maximum temperature needed to elute compounds.[30] One major advantage of automating purification is the scale at which separations can be done.[31] Using microprocessors, ion-exchange separation can be conducted on a nanoliter scale in a short period of time.

Robotics have been implemented in liquid-liquid extraction (LLE) to streamline the process of preparing biological samples using 96-well plates.[32] This is an alternative method to solid-phase extraction methods and protein precipitation, which has the advantage of being more reproducible and robotic assistance has made LLE comparable in speed to solid phase extraction. The robotics used for LLE can perform an entire extraction with quantities in the microliter scale and performing the extraction in as little as ten minutes.

Advantages and disadvantages

Advantages

One of the advantages to automation is faster processing, but it is not necessarily faster than a human operator. Repeatability and reproducibility are improved as automated systems as less likely to have variances in reagent quantities and less likely to have variances in reaction conditions. Typically productivity is increased since human constraints, such as time constraints, are no longer a factor. Efficiency is generally improved as robots can work continuously and reduce the amount of reagents used to perform a reaction. Also there is a reduction in material waste. Automation can also establish safer working environments since hazardous compounds do not have to be handled. Additionally automation allows staff to focus on other tasks that are not repetitive.

Disadvantages

Typically the cost of a single synthesis or sample assessment are expensive to set up and start up cost for automation can be expensive (but see above "Low-cost laboratory robotics"). Many techniques have not been developed for automation yet. Additionally there is difficulty automating instances where visual analysis, recognition, or comparison is required such as color changes. This also leads to the analysis being limited by available sensory inputs. One potential disadvantage is an increases job shortages as automation may replace staff members who do tasks easily replicated by a robot. Some systems require the use of programming languages such as C++ or Visual Basic to run more complicated tasks.[33]

See also

References

  1. ^ Mortimer, James A.; Hurst, W. Jeffrey (1987). Laboratory robotics: a guide to planning, programming, and applications. New York, N.Y: VCH Publishers. ISBN 978-0-89573-322-1.
  2. ^ Ward, K. B.; Perozzo, M. A.; Zuk, W. M. (1988). "Automatic preparation of protein crystals using laboratory robotics and automated visual inspection". Journal of Crystal Growth. 90 (1–3): 325–339. Bibcode:1988JCrGr..90..325W. doi:10.1016/0022-0248(88)90328-4.
  3. ^ King, R. D.; Whelan, K. E.; Jones, F. M.; Reiser, P. G. K.; Bryant, C. H.; Muggleton, S. H.; Kell, D. B.; Oliver, S. G. (2004). "Functional genomic hypothesis generation and experimentation by a robot scientist". Nature. 427 (6971): 247–252. Bibcode:2004Natur.427..247K. doi:10.1038/nature02236. PMID 14724639.
  4. ^ a b Boyd, James (2002-01-18). "Robotic Laboratory Automation". Science. 295 (5554): 517–518. doi:10.1126/science.295.5554.517. ISSN 0036-8075. PMID 11799250.
  5. ^ Felder, Robin A. (2006-04-01). "The Clinical Chemist: Masahide Sasaki, MD, PhD (August 27, 1933–September 23, 2005)". Clinical Chemistry. 52 (4): 791–792. doi:10.1373/clinchem.2006.067686. ISSN 0009-9147.
  6. ^ a b Felder, Robin A (1998-12-01). "Modular workcells: modern methods for laboratory automation". Clinica Chimica Acta. 278 (2): 257–267. doi:10.1016/S0009-8981(98)00151-X. PMID 10023832.
  7. ^ Bär, Henning; Hochstrasser, Remo; Papenfuß, Bernd (2012-04-01). "SiLA Basic Standards for Rapid Integration in Laboratory Automation". Journal of Laboratory Automation. 17 (2): 86–95. doi:10.1177/2211068211424550. ISSN 2211-0682. PMID 22357556.
  8. ^ Pearce, Joshua M. (2014-01-01). "Introduction to Open-Source Hardware for Science". Chapter 1 - Introduction to Open-Source Hardware for Science. Boston: Elsevier. pp. 1–11. doi:10.1016/b978-0-12-410462-4.00001-9. ISBN 9780124104624.
  9. ^ a b Carvalho, Matheus C. (2013-08-01). "Integration of Analytical Instruments with Computer Scripting". Journal of Laboratory Automation. 18 (4): 328–333. doi:10.1177/2211068213476288. ISSN 2211-0682. PMID 23413273.
  10. ^ Carvalho, Matheus C.; Eyre, Bradley D. (2013-12-01). "A low cost, easy to build, portable, and universal autosampler for liquids". Methods in Oceanography. 8: 23–32. doi:10.1016/j.mio.2014.06.001.
  11. ^ Carvalho, Matheus (2017). Practical Laboratory Automation: Made Easy with AutoIt. Wiley VCH.
  12. ^ "Researchers build robot scientist that has already discovered a new catalyst". phys.org. Retrieved 16 August 2020.
  13. ^ Burger, Benjamin; Maffettone, Phillip M.; Gusev, Vladimir V.; Aitchison, Catherine M.; Bai, Yang; Wang, Xiaoyan; Li, Xiaobo; Alston, Ben M.; Li, Buyi; Clowes, Rob; Rankin, Nicola; Harris, Brandon; Sprick, Reiner Sebastian; Cooper, Andrew I. (July 2020). "A mobile robotic chemist". Nature. 583 (7815): 237–241. doi:10.1038/s41586-020-2442-2. ISSN 1476-4687. Retrieved 16 August 2020.
  14. ^ "Robots Get Ready to Roam in Clinical Labs | AACC.org". www.aacc.org. Retrieved 25 May 2022.
  15. ^ Gary A. McClusky, Brian Tobias. "Automation of Structure Analysis in Pharmaceutical R&D." Journal of Management of Information Systems (1996).
  16. ^ Heinemann, Udo, Gerd Illing, and Hartmut Oschkinat. "High-Throughput Three-Dimensional Protein Structure Determination." Current Opinion in Biotechnology 12.4 (2001): 348-54.
  17. ^ "'Robot scientist' Eve finds that less than one-third of scientific results are reproducible". University of Cambridge. Retrieved 15 May 2022.
  18. ^ Roper K, Abdel-Rehim A, Hubbard S, Carpenter M, Rzhetsky A, Soldatova L, King RD (April 2022). "Testing the reproducibility and robustness of the cancer biology literature by robot". Journal of the Royal Society, Interface. 19 (189): 20210821. doi:10.1098/rsif.2021.0821. PMC 8984295. PMID 35382578.
  19. ^ Sanders, Robert (30 March 2020). "UC Berkeley scientists spin up a robotic COVID-19 testing lab". Berkeley News. Retrieved 25 May 2022.
  20. ^ "Robot automates COVID-19 testing". healthcare-in-europe.com. Retrieved 25 May 2022.
  21. ^ "CDC B-Roll | CDC Online Newsroom | CDC". www.cdc.gov. 30 March 2022. Retrieved 25 May 2022. This b-roll depicts the lab work involved in serology testing. This laboratory robot performs all the steps of the SARS-CoV-2 antibody test from sample loading through antibody detection in one workflow, and it can test over 3,600 samples a day. A public health scientist can test about 400 samples a day by hand. The use of automated laboratory robots will improve antibody testing capacity, resulting in more data to help monitor and respond to the COVID-19 pandemic.
  22. ^ Anderson, Caitlin E.; Huynh, Toan; Gasperino, David J.; Alonzo, Luis F.; Cantera, Jason L.; Harston, Stephen P.; Hsieh, Helen V.; Marzan, Rosemichelle; McGuire, Shawn K.; Williford, John R.; Oncina, Ciela I.; Glukhova, Veronika A.; Bishop, Joshua D.; Cate, David M.; Grant, Benjamin D.; Nichols, Kevin P.; Weigl, Bernhard H. (1 March 2022). "Automated liquid handling robot for rapid lateral flow assay development". Analytical and Bioanalytical Chemistry. 414 (8): 2607–2618. doi:10.1007/s00216-022-03897-9. ISSN 1618-2650.
  23. ^ Barsoum, I. S.; Awad, A. Y. (1972). "Microtiter plate agglutination test for Salmonella antibodies". Applied Microbiology. 23 (2): 425–426. doi:10.1128/AEM.23.2.425-426.1972. PMC 380357. PMID 5017681.
  24. ^ "Microplate Standardization, Report 3" submitted by T. Astle Journal of Biomolecular Screening (1996). Vol. 1 No. 4, pp 163-168.
  25. ^ hands-free use of pipettes, October 2012, retrieved September 30, 2012
  26. ^ Nicholas W Hird Drug Discovery Today, Volume 4, Issue 6, p.265-274 (1999) [1]
  27. ^ David Cork, Tohru Sugawara. Laboratory Automation in the Chemical Industries. CRC Press, 2002.
  28. ^ Hardin, J.; Smietana, F., Automating combinatorial chemistry: A primer on benchtop robotic systems. Mol Divers 1996, 1 (4), 270-274.
  29. ^ H. M. Geysen, R. H. Meloen, S. J. Barteling Proc. Natl. Acad. Sci. USA 1984, 81, 3998.
  30. ^ William F. Berry, V. G., Automated simulated distillation using an articulated laboratory robot system. Journal of Automatic Chemistry 1994, 16 (6), 205-209.
  31. ^ Paegel, Brian M., Stephanie H. I. Yeung, and Richard A. Mathies. "Microchip Bioprocessor for Integrated Nanovolume Sample Purification and DNA Sequencing." Analytical chemistry 74.19 (2002): 5092-98.
  32. ^ Peng, S. X.; Branch, T. M.; King, S. L., Fully Automated 96-Well Liquid−Liquid Extraction for Analysis of Biological Samples by Liquid Chromatography with Tandem Mass Spectrometry. Analytical Chemistry 2000, 73 (3), 708-714.
  33. ^ Cargill, J. F.; Lebl, M., New methods in combinatorial chemistry — robotics and parallel synthesis. Current Opinion in Chemical Biology 1997, 1 (1), 67-71.

February 06, 2023
laboratory, robotics, using, robots, biology, chemistry, engineering, labs, example, pharmaceutical, companies, employ, robots, move, biological, chemical, samples, around, synthesize, novel, chemical, entities, test, pharmaceutical, value, existing, chemical,. Laboratory robotics is the act of using robots in biology chemistry or engineering labs For example pharmaceutical companies employ robots to move biological or chemical samples around to synthesize novel chemical entities or to test pharmaceutical value of existing chemical matter 1 2 Advanced laboratory robotics can be used to completely automate the process of science as in the Robot Scientist project 3 Laboratory robots doing acid digestion chemical analysis Laboratory processes are suited for robotic automation as the processes are composed of repetitive movements e g pick place liquid solid additions heating cooling mixing shaking and testing Many laboratory robots are commonly referred as autosamplers as their main task is to provide continuous samples for analytical devices Contents 1 History 2 Applications 2 1 Low cost laboratory robotics 2 2 Robotic mobile laboratory operators and remote controlled laboratories 2 3 Pharmaceutical applications 2 4 Reproducibility verification 2 5 Diagnostic testing for pathogens 2 6 Biological laboratory robotics 2 7 Combinatorial library synthesis 2 8 Purification 3 Advantages and disadvantages 3 1 Advantages 3 2 Disadvantages 4 See also 5 ReferencesHistory EditThe first compact computer controlled robotic arms appeared in the early 1980s and have continuously been employed in laboratories since then 4 These robots can be programmed to perform many different tasks including sample preparation and handling Yet in the early 1980s a group led by Masahide Sasaki from Kochi Medical School introduced the first fully automated laboratory employing several robotic arms working together with conveyor belts and automated analyzers 4 5 The success of Sasaki s pioneer efforts made other groups around the world to adopt the approach of Total Laboratory Automation TLA Despite the undeniable success of TLA its multimillion dollar cost prevented that most laboratories adopted it 6 Also the lack of communication between different devices slowed down the development of automation solutions for different applications while contributing to keeping costs high Therefore the industry attempted several times to develop standards that different vendors would follow in order to enable communication between their devices 6 7 However the success of this approach has been only partial as nowadays many laboratories still do not employ robots for many tasks due to their high costs Recently a different solution for the problem became available enabling the use of inexpensive devices including open source hardware 8 to perform many different tasks in the laboratory This solution is the use of scripting languages that can control mouse clicks and keyboard inputs like AutoIt 9 This way it is possible to integrate any device by any manufacturer as long as they are controlled by a computer which is often the case Another important development in robotics which has important potential implications for laboratories is the arrival of robots that do not demand special training for their programming like Baxter the robot Applications EditLow cost laboratory robotics Edit Low cost robotic arm used as an autosampler The high cost of many laboratory robots has inhibited their adoption However currently there are many robotic devices that have very low cost and these could be employed to do some jobs in a laboratory For example a low cost robotic arm was employed to perform several different kinds of water analysis without loss of performance compared to much more expensive autosamplers 10 Alternatively the autosampler of a device can be used with another device 9 thus avoiding the need for purchasing a different autosampler or hiring a technician for doing the job The key aspects to achieve low cost in laboratory robotics are 1 the use of low cost robots which become more and more common and 2 the use of scripting which enables compatibility between robots and other analytical equipment 11 Robotic mobile laboratory operators and remote controlled laboratories Edit In July 2020 scientists reported the development of a mobile robot chemist and demonstrate that it can assist in experimental searches According to the scientists their strategy was automating the researcher rather than the instruments freeing up time for the human researchers to think creatively and could identify photocatalyst mixtures for hydrogen production from water that were six times more active than initial formulations The modular robot can operate laboratory instruments work nearly around the clock and autonomously make decisions on his next actions depending on experimental results 12 13 There is ongoing development of remote controlled laboratories that automatically perform many life sciences experiments per day and can be operated including in collaboration from afar 14 Pharmaceutical applications Edit One major area where automated synthesis has been applied is structure determination in pharmaceutical research Processes such as NMR and HPLC MS can now have sample preparation done by robotic arm 15 Additionally structural protein analysis can be done automatically using a combination of NMR and X ray crystallography Crystallization often takes hundreds to thousands of experiments to create a protein crystal suitable for X ray crystallography 16 An automated micropipet machine can allow nearly a million different crystals to be created at once and analyzed via X ray crystallography Reproducibility verification Edit This section is an excerpt from Replication crisis Semi automated edit The overall process of testing the reproducibility and robustness of the cancer biology literature by robot First text mining is used to extract statements about the effect of drugs on gene expression in breast cancer Then two different teams semi automatically tested these statements using two different protocols and two different cell lines MCF7 and MDA MB 231 using the laboratory automation system Eve Researchers demonstrated a way of semi automated testing for reproducibility statements about experimental results were extracted from as of 2022 non semantic gene expression cancer research papers and subsequently reproduced via robot scientist Eve 17 18 Problems of this approach include that it may not be feasible for many areas of research and that sufficient experimental data may not get extracted from some or many papers even if available Diagnostic testing for pathogens Edit See also Medical diagnosis and Diagnostic robot This section needs expansion You can help by adding to it May 2022 For example there are robots that are used to analyze swabs from patients to diagnose COVID 19 19 20 21 Automated robotic liquid handling systems have been or are being built for lateral flow assays It minimizes hands on time maximizes experiment size and enables improved reproducibility 22 Biological laboratory robotics Edit An example of pipettes and microplates manipulated by an anthropomorphic robot Andrew Alliance Biological and chemical samples in either liquid or solid state are stored in vials plates or tubes Often they need to be frozen and or sealed to avoid contamination or to retain their biological and or chemical properties Specifically the life science industry has standardized on a plate format known as the microtiter plate 23 to store such samples The microtiter plate standard was formalized by the Society for Biomolecular Screening in 1996 24 It typically has 96 384 or even 1536 sample wells arranged in a 2 3 rectangular matrix The standard governs well dimensions e g diameter spacing and depth as well as plate properties e g dimensions and rigidity A number of companies have developed robots to specifically handle SBS microplates Such robots may be liquid handlers which aspirates or dispenses liquid samples from and to these plates or plate movers which transport them between instruments Other companies have pushed integration even further on top of interfacing to the specific consumables used in biology some robots Andrew 25 by Andrew Alliance see picture have been designed with the capability of interfacing to volumetric pipettes used by biologists and technical staff Essentially all the manual activity of liquid handling can be performed automatically allowing humans spending their time in more conceptual activities Instrument companies have designed plate readers which can carry out detect specific biological chemical or physical events in samples stored in these plates These readers typically use optical and or computer vision techniques to evaluate the contents of the microtiter plate wells One of the first applications of robotics in biology was peptide and oligonucleotide synthesis One early example is the polymerase chain reaction PCR which is able to amplify DNA strands using a thermal cycler to micromanage DNA synthesis by adjusting temperature using a pre made computer program Since then automated synthesis has been applied to organic chemistry and expanded into three categories reaction block systems robot arm systems and non robotic fluidic systems 26 The primary objective of any automated workbench is high throughput processes and cost reduction 27 This allows a synthetic laboratory to operate with a fewer number of people working more efficiently Combinatorial library synthesis Edit Robotics have applications with combinatorial chemistry which has great impact on the pharmaceutical industry The use of robotics has allowed for the use of much smaller reagent quantities and mass expansion of chemical libraries The parallel synthesis method can be improved upon with automation The main disadvantage to parallel synthesis is the amount of time it takes to develop a library automation is typically applied to make this process more efficient The main types of automation are classified by the type of solid phase substrates the methods for adding and removing reagents and design of reaction chambers Polymer resins may be used as a substrate for solid phase 28 It is not a true combinatorial method in the sense that split mix where a peptide compound is split into different groups and reacted with different compounds This is then mixed back together split into more groups and each groups is reacted with a different compound Instead the parallel synthesis method does not mix but reacts different groups of the same peptide with different compounds and allows for the identification of the individual compound on each solid support A popular method implemented is the reaction block system due to its relative low cost and higher output of new compounds compared to other parallel synthesis methods Parallel Synthesis was developed by Mario Geysen and his colleagues and is not a true type of combinatorial synthesis but can be incorporated into a combinatorial synthesis 29 This group synthesized 96 peptides on plastic pins coated with a solid support for the solid phase peptide synthesis This method uses a rectangular block moved by a robot so that reagents can be pipetted by a robotic pipetting system This block is separated into wells which the individual reactions take place These compounds are later cleaved from the solid phase of the well for further analysis Another method is the closed reactor system which uses a completely closed off reaction vessel with a series of fixed connections to dispense Though the produce fewer number of compounds than other methods its main advantage is the control over the reagents and reaction conditions Early closed reaction systems were developed for peptide synthesis which required variations in temperature and a diverse range of reagents Some closed reactor system robots have a temperature range of 200 C and over 150 reagents Purification Edit Simulated distillation a type of gas chromatography testing method used in the petroleum can be automated via robotics An older method used a system called ORCA Optimized Robot for Chemical Analysis was used for the analysis of petroleum samples by simulated distillation SIMDIS ORCA has allowed for shorter analysis times and has reduced maximum temperature needed to elute compounds 30 One major advantage of automating purification is the scale at which separations can be done 31 Using microprocessors ion exchange separation can be conducted on a nanoliter scale in a short period of time Robotics have been implemented in liquid liquid extraction LLE to streamline the process of preparing biological samples using 96 well plates 32 This is an alternative method to solid phase extraction methods and protein precipitation which has the advantage of being more reproducible and robotic assistance has made LLE comparable in speed to solid phase extraction The robotics used for LLE can perform an entire extraction with quantities in the microliter scale and performing the extraction in as little as ten minutes Advantages and disadvantages EditAdvantages Edit One of the advantages to automation is faster processing but it is not necessarily faster than a human operator Repeatability and reproducibility are improved as automated systems as less likely to have variances in reagent quantities and less likely to have variances in reaction conditions Typically productivity is increased since human constraints such as time constraints are no longer a factor Efficiency is generally improved as robots can work continuously and reduce the amount of reagents used to perform a reaction Also there is a reduction in material waste Automation can also establish safer working environments since hazardous compounds do not have to be handled Additionally automation allows staff to focus on other tasks that are not repetitive Disadvantages Edit Typically the cost of a single synthesis or sample assessment are expensive to set up and start up cost for automation can be expensive but see above Low cost laboratory robotics Many techniques have not been developed for automation yet Additionally there is difficulty automating instances where visual analysis recognition or comparison is required such as color changes This also leads to the analysis being limited by available sensory inputs One potential disadvantage is an increases job shortages as automation may replace staff members who do tasks easily replicated by a robot Some systems require the use of programming languages such as C or Visual Basic to run more complicated tasks 33 See also EditCloud laboratory Laboratory automation List of emerging technologies MedicalReferences Edit Mortimer James A Hurst W Jeffrey 1987 Laboratory robotics a guide to planning programming and applications New York N Y VCH Publishers ISBN 978 0 89573 322 1 Ward K B Perozzo M A Zuk W M 1988 Automatic preparation of protein crystals using laboratory robotics and automated visual inspection Journal of Crystal Growth 90 1 3 325 339 Bibcode 1988JCrGr 90 325W doi 10 1016 0022 0248 88 90328 4 King R D Whelan K E Jones F M Reiser P G K Bryant C H Muggleton S H Kell D B Oliver S G 2004 Functional genomic hypothesis generation and experimentation by a robot scientist Nature 427 6971 247 252 Bibcode 2004Natur 427 247K doi 10 1038 nature02236 PMID 14724639 a b Boyd James 2002 01 18 Robotic Laboratory Automation Science 295 5554 517 518 doi 10 1126 science 295 5554 517 ISSN 0036 8075 PMID 11799250 Felder Robin A 2006 04 01 The Clinical Chemist Masahide Sasaki MD PhD August 27 1933 September 23 2005 Clinical Chemistry 52 4 791 792 doi 10 1373 clinchem 2006 067686 ISSN 0009 9147 a b Felder Robin A 1998 12 01 Modular workcells modern methods for laboratory automation Clinica Chimica Acta 278 2 257 267 doi 10 1016 S0009 8981 98 00151 X PMID 10023832 Bar Henning Hochstrasser Remo Papenfuss Bernd 2012 04 01 SiLA Basic Standards for Rapid Integration in Laboratory Automation Journal of Laboratory Automation 17 2 86 95 doi 10 1177 2211068211424550 ISSN 2211 0682 PMID 22357556 Pearce Joshua M 2014 01 01 Introduction to Open Source Hardware for Science Chapter 1 Introduction to Open Source Hardware for Science Boston Elsevier pp 1 11 doi 10 1016 b978 0 12 410462 4 00001 9 ISBN 9780124104624 a b Carvalho Matheus C 2013 08 01 Integration of Analytical Instruments with Computer Scripting Journal of Laboratory Automation 18 4 328 333 doi 10 1177 2211068213476288 ISSN 2211 0682 PMID 23413273 Carvalho Matheus C Eyre Bradley D 2013 12 01 A low cost easy to build portable and universal autosampler for liquids Methods in Oceanography 8 23 32 doi 10 1016 j mio 2014 06 001 Carvalho Matheus 2017 Practical Laboratory Automation Made Easy with AutoIt Wiley VCH Researchers build robot scientist that has already discovered a new catalyst phys org Retrieved 16 August 2020 Burger Benjamin Maffettone Phillip M Gusev Vladimir V Aitchison Catherine M Bai Yang Wang Xiaoyan Li Xiaobo Alston Ben M Li Buyi Clowes Rob Rankin Nicola Harris Brandon Sprick Reiner Sebastian Cooper Andrew I July 2020 A mobile robotic chemist Nature 583 7815 237 241 doi 10 1038 s41586 020 2442 2 ISSN 1476 4687 Retrieved 16 August 2020 Robots Get Ready to Roam in Clinical Labs AACC org www aacc org Retrieved 25 May 2022 Gary A McClusky Brian Tobias Automation of Structure Analysis in Pharmaceutical R amp D Journal of Management of Information Systems 1996 Heinemann Udo Gerd Illing and Hartmut Oschkinat High Throughput Three Dimensional Protein Structure Determination Current Opinion in Biotechnology 12 4 2001 348 54 Robot scientist Eve finds that less than one third of scientific results are reproducible University of Cambridge Retrieved 15 May 2022 Roper K Abdel Rehim A Hubbard S Carpenter M Rzhetsky A Soldatova L King RD April 2022 Testing the reproducibility and robustness of the cancer biology literature by robot Journal of the Royal Society Interface 19 189 20210821 doi 10 1098 rsif 2021 0821 PMC 8984295 PMID 35382578 Sanders Robert 30 March 2020 UC Berkeley scientists spin up a robotic COVID 19 testing lab Berkeley News Retrieved 25 May 2022 Robot automates COVID 19 testing healthcare in europe com Retrieved 25 May 2022 CDC B Roll CDC Online Newsroom CDC www cdc gov 30 March 2022 Retrieved 25 May 2022 This b roll depicts the lab work involved in serology testing This laboratory robot performs all the steps of the SARS CoV 2 antibody test from sample loading through antibody detection in one workflow and it can test over 3 600 samples a day A public health scientist can test about 400 samples a day by hand The use of automated laboratory robots will improve antibody testing capacity resulting in more data to help monitor and respond to the COVID 19 pandemic Anderson Caitlin E Huynh Toan Gasperino David J Alonzo Luis F Cantera Jason L Harston Stephen P Hsieh Helen V Marzan Rosemichelle McGuire Shawn K Williford John R Oncina Ciela I Glukhova Veronika A Bishop Joshua D Cate David M Grant Benjamin D Nichols Kevin P Weigl Bernhard H 1 March 2022 Automated liquid handling robot for rapid lateral flow assay development Analytical and Bioanalytical Chemistry 414 8 2607 2618 doi 10 1007 s00216 022 03897 9 ISSN 1618 2650 Barsoum I S Awad A Y 1972 Microtiter plate agglutination test for Salmonella antibodies Applied Microbiology 23 2 425 426 doi 10 1128 AEM 23 2 425 426 1972 PMC 380357 PMID 5017681 Microplate Standardization Report 3 submitted by T Astle Journal of Biomolecular Screening 1996 Vol 1 No 4 pp 163 168 hands free use of pipettes October 2012 retrieved September 30 2012 Nicholas W Hird Drug Discovery Today Volume 4 Issue 6 p 265 274 1999 1 David Cork Tohru Sugawara Laboratory Automation in the Chemical Industries CRC Press 2002 Hardin J Smietana F Automating combinatorial chemistry A primer on benchtop robotic systems Mol Divers 1996 1 4 270 274 H M Geysen R H Meloen S J Barteling Proc Natl Acad Sci USA 1984 81 3998 William F Berry V G Automated simulated distillation using an articulated laboratory robot system Journal of Automatic Chemistry 1994 16 6 205 209 Paegel Brian M Stephanie H I Yeung and Richard A Mathies Microchip Bioprocessor for Integrated Nanovolume Sample Purification and DNA Sequencing Analytical chemistry 74 19 2002 5092 98 Peng S X Branch T M King S L Fully Automated 96 Well Liquid Liquid Extraction for Analysis of Biological Samples by Liquid Chromatography with Tandem Mass Spectrometry Analytical Chemistry 2000 73 3 708 714 Cargill J F Lebl M New methods in combinatorial chemistry robotics and parallel synthesis Current Opinion in Chemical Biology 1997 1 1 67 71 Retrieved from https en wikipedia org w index php title Laboratory robotics amp oldid 1136250989, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.